JP7374774B2 - Heat source control system and heat source control method - Google Patents

Description

The present invention relates to a heat source control system and a heat source control method.

It is a method that optimizes the operation plan of equipment such as air conditioning heat source equipment, generators, and storage batteries using optimization methods such as mathematical programming, and allows the entire system to operate at lower energy and cost while keeping power demand to the target. It has been proposed (for example, Patent Document 1). Using this method, an optimal solution can be found as to what percentage of the rated output each device should operate at for each unit of time, such as 30 minutes or 1 hour.

On the other hand, an air conditioning heat source device (hereinafter referred to as a heat source device) currently uses an automatic control device called a heat source controller for system protection and performance maintenance (for example, see the "Prior Art" section of Patent Document 2). Heat source controllers have been made general-purpose by control manufacturers, and their use may be required in terms of cost and system design.

The main functions of the heat source controller are as follows. (1) System protection: Excluding heat source equipment undergoing maintenance or malfunctioning heat source equipment, and equalizing operating hours through rotation. (2) Performance maintenance: Controlling the number of units based on fluctuations in the secondary heat load (automatically increasing/decreasing stages to operate only the necessary heat source equipment), automatically increasing stages when the water supply temperature rises, and automatically decreasing stages when the return temperature decreases.

Patent No. 5696877 Japanese Patent Application Publication No. 8-42933

The heat source controller described above operates the heat source devices by controlling the number of heat source devices. In the number control, the activation order is determined in advance, and the number of devices required for secondary side heat load processing is activated according to the activation order. Further, the output of each heat source device is divided equally, for example. Further, the starting order is fixed and does not change, for example. In this example, for example, if the chilled water load is 250 kW, machine A: rated output 130 kW, machine B: rated output 100 kW, machine C: rated output 90 kW, machine D 70 kW, and the startup order is A→B→C→D, machine A, B Machine and Machine C are activated in this order, and the output percentage of each machine becomes 250/(130+100+90)=78%, resulting in all machines outputting at the same rate. Here, the output % represents the ratio of the output to the rated output. On the other hand, the optimal solution for the operation plan is determined as a solution in which any heat source equipment operates at any output. For this reason, the heat source controller described above cannot operate according to the optimal solution. For example, for a plan in which at 10:00 the power will be 130 kW for Aircraft A, 100 kW for Aircraft B, 20 kW for Aircraft D, and 100 kW for Aircraft B, 90 kW for Aircraft C, and 60 kW for Aircraft D at 10:30, the above This cannot be done with a heat source controller.

The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a heat source control system and a heat source control method that can operate as close to the optimal solution as possible using the heat source controller described above.

In order to solve the above problems, one aspect of the present invention is a system that controls a plurality of heat source devices, the system includes a heat source controller and a central control device, and the heat source controller is configured to respond to fluctuations in secondary side heat load. Accordingly, a number control unit increases or decreases the number of operating heat source devices according to the startup order instructed by the central control device, and stops the instructed heat source devices based on the stop instruction received from the central control device. a stop control unit, wherein the central control unit includes a storage unit that stores a startup order table including a plurality of combinations of the startup orders, and a storage unit that stores a start order table including a plurality of combinations of the start orders, and a stop control unit that defines a schedule for each output of each heat source device for each unit time. a second operation plan creation unit that creates a second operation plan that defines one combination selected from the startup order table based on the first operation plan and a period covered by the stop instruction determined based on the first operation plan; and an instruction transmitter that transmits the start order instruction and the stop instruction to the heat source controller based on the second operation plan.

Further, one aspect of the present invention is a method of controlling a plurality of heat source devices, using a heat source controller and a central control device, in the heat source controller, the a step of increasing or decreasing the number of operating heat source devices according to a startup order instructed by a central control device; a step of stopping the instructed heat source devices based on a stop instruction received from the central control device; and a step of stopping the instructed heat source devices; In the apparatus, one combination selected from a startup order table including a plurality of combinations of the startup orders based on a first operation plan that defines a schedule for each output of each heat source device for each unit time, and the first operation plan. creating a second operation plan that defines the target period of the stop instruction determined based on the second operation plan; and transmitting the start order instruction and the stop instruction to the heat source controller based on the second operation plan. A heat source control method includes steps.

According to each aspect of the present invention, the heat source controller operates a plurality of Since the heat source devices are controlled, each heat source device can be operated in a state closer to the first operation plan.

1 is a configuration diagram showing a configuration example of an air conditioning system according to an embodiment of the present invention. FIG. 2 is a configuration diagram showing a configuration example of a startup order table according to an embodiment of the present invention. FIG. 2 is a schematic diagram showing an example of an operation plan according to an embodiment of the present invention. FIG. 2 is a schematic diagram showing an example of an operation plan according to an embodiment of the present invention. FIG. 2 is a schematic diagram showing the flow of processing according to an embodiment of the present invention. 1 is a schematic diagram showing a configuration example of a system according to an embodiment of the present invention.

Embodiments of the present invention will be described below with reference to the drawings. In addition, in each figure, the same reference numerals are used for the same or corresponding components, and the description thereof will be omitted as appropriate.

FIG. 1 is a configuration diagram showing a configuration example of an air conditioning system 100 according to an embodiment of the present invention. The air conditioning system 100 shown in FIG. 1 includes a heat source control system 1, a first operation plan creation device 4, and a heat source system 5. The heat source control system 1 includes a central control device 2 and a heat source controller 3. The heat source system 5 includes a secondary load 51, a heat source device 52, a heat source device 53, a primary pump 54, a primary pump 55, a temperature sensor 56, a temperature sensor 57, a flow rate sensor 58, and a header. 61, a header 62, piping 63, and piping 64.

The secondary side load 51 is composed of a plurality of devices such as an air conditioner that provides a heat load to the heat source device 52 and the heat source device 53. Cold water or hot water produced by the heat source device 52 and the heat source device 53 is supplied to the secondary side load 51 via a header 61 and piping 63. Further, the cold water or hot water that has passed through the secondary load 51 is returned to the heat source device 52 or 53 via the piping 64, the header 62, and the primary pump 54 or 55.

The heat source device 52 and the heat source device 53 are heat source devices (heat source devices) such as refrigerators, cold/hot water machines, and heat pumps, and are cold water or The hot water outlet temperature is controlled to a predetermined temperature. Further, the heat source device 52 and the heat source device 53 are started or stopped according to a predetermined control signal sent from the heat source controller 3.

In addition, in this embodiment, the heat source device 52 is assumed to be an air-cooled heat pump whose main power source is electric power. It is also assumed that the heat source device 53 is a gas absorption cold/hot water device whose main power source is gas. Furthermore, it is assumed that the heat source device 52 is a heat source device with higher power consumption and lower operating cost than the heat source device 53. Furthermore, it is assumed that the heat source device 53 is a heat source device with lower power consumption and higher operating cost than the heat source device 52.

The temperature sensor 56 detects the temperature of cold water or hot water (secondary side outgoing temperature) sent from the header 61 to the secondary side heat load 51 via the piping 63, and sends a signal indicating the detected temperature to the heat source controller 3. and output it. The temperature sensor 57 detects the temperature of cold water or hot water (secondary return temperature) sent from the secondary heat load 51 to the header 62 via the piping 64, and sends a signal indicating the detected temperature to the heat source controller 3. and output it. The flow rate sensor 58 detects the flow rate of cold water or hot water flowing through the pipe 64 and outputs a signal indicating the detected flow rate to the heat source controller 3.

The primary pump 54 sends cold water or hot water from the header 62 to the heat source device 52 . The primary pump 55 sends cold water or hot water from the header 62 to the heat source device 52 . The primary pump 54 and the primary pump 55 start or stop, or control the rotational speed of the internal motor, according to a predetermined control signal sent from the heat source controller 3.

The heat source controller 3 is configured using a control device including a computer such as a PLC (Programmable Logic Controller), and includes hardware including the computer, peripheral devices of the computer, etc., and programs executed by the computer. A communication section 31, a number control section 32, a stop control section 33, and an input/output section 34 are provided as a functional configuration configured in combination with software.

The communication unit 31 receives from the central control device 2 a signal for instructing the starting order of the heat source device 52 and the heat source device 53, a stop instruction for instructing to stop the heat source device 52 and the heat source device 53, and Data indicating the temperature, flow rate, etc. detected by the heat source system 5 is transmitted to the control device 2.

The number control unit 32 increases or decreases the number of operating heat source devices 52 and 53 according to the startup order instructed by the central control device 2 in accordance with fluctuations in the secondary heat load. For example, the number control unit 32 sets the number of operating heat source devices to 0, 0, or 1 in accordance with the startup order based on the temperature detected by the temperature sensor 56, the temperature detected by the temperature sensor 57, and the flow rate detected by the flow rate sensor 58. Change to 1 or 2 units.

Based on the stop instruction received from the central control device 2, the stop control unit 33 stops (does not start) the instructed heat source device 52, heat source device 53, or both for a period during which the stop instruction is valid.

The input/output unit 34 inputs a signal indicating the temperature detected by the temperature sensor 56, a signal indicating the temperature detected by the temperature sensor 57, and a signal indicating the flow rate detected by the flow rate sensor 58, and also inputs a signal indicating the temperature detected by the temperature sensor 56, and a signal indicating the flow rate detected by the flow rate sensor 58. A predetermined control signal that instructs the pump 53 to start or stop, and a predetermined control signal that instructs the primary pump 54 and the primary pump 55 to start or stop or the rotation speed are output.

On the other hand, the first operation planning device 4 is a computer such as a server or a personal computer, and is a computer that determines the schedule (prediction) of each output of the heat source device 52 and the heat source device 53 for each unit time (for example, every 30 minutes). 1 Create an operation plan. For example, as described in Patent Document 1, the first operation planning device 4 uses a mathematical programming method to save energy, save costs, or save CO2 (carbon dioxide) and satisfy power demand constraints. Create the first operation plan. The scheduled value of each output is a value that is optimal when the vehicle is operated at that value, and is a target value of the operating output. Note that the first operation plan may include, for example, a predicted value of a predetermined power load for each unit time. Here, the predetermined power load (device that consumes power) is a power load that is subject to power demand (power suppression by contract power or demand response), and for example, the power load that the heat source device 52 and the heat source device 53 have. , the power load of the primary pump 54 and the primary pump 55, the power load of the secondary heat load 51, and the power load of equipment and equipment of the facility where the secondary heat load 51 is installed. Moreover, the predetermined power load does not need to include the power load that the heat source device 52 and the heat source device 53 have, and the power load that the primary pump 54 and the primary pump 55 have. Further, the first operation plan may include, for example, a power supply operation plan indicating a charging/discharging schedule of the power storage equipment for each unit time.

3 and 4 are schematic diagrams showing examples of operation plans according to this embodiment. Figures 3 and 4 show the operation plans (first operation plan, second operation plan and third operation plan described later) for one day (for example, from 0:00 the next day to 0:00 the day after the next day (24:00 of the next day)). Here is an example of a plan. The first operation plan shown in FIGS. 3 and 4 defines a schedule for the output (% output) of the heat source device 52 (air-cooled heat pump) and the heat source device 53 (gas absorption type cold/hot water machine) every 30 minutes. In the example shown in FIG. 3, the scheduled output (% output) of the heat source device 53 (gas absorption type cold/hot water device) is 0% all day long. In the example shown in FIG. 4, the scheduled output (% output) of the heat source device 53 (gas absorption type cold/hot water device) is a value larger than 0% from 10:00 to 16:00. In addition, in the example shown in FIG. 3 and the example shown in FIG. % output) are both scheduled to be 0%.

The first driving plan creation device 4 creates, for example, a file showing the first driving plan as shown in FIGS. 3 and 4, and the created file showing the first driving plan is stored on a predetermined recording medium or communication line. is inputted to the central control device 2 via. Note that the first operation plan creation device 4 may be configured to be included in the central control device 2, for example.

Further, the central control device 2 is configured using a computer such as a server or a personal computer, and is configured by a combination of hardware such as the computer and peripheral devices of the computer, and software such as a program executed by the computer. The functional configuration includes a communication section 21, a storage section 22, an input section 23, a second operation plan creation section 24, and an instruction transmission section 25.

The communication unit 21 transmits to the heat source controller 3 a signal for instructing the starting order of the heat source device 52 and the heat source device 53, and a stop instruction for instructing to stop the heat source device 52 and the heat source device 53. , data indicating the temperature, flow rate, etc. detected by the heat source system 5 is received from the heat source controller 3 .

The storage unit 22 stores a startup order table including a plurality of combinations of startup orders of the heat source devices 52 and 53. FIG. 2 is a configuration diagram showing an example of the configuration of the startup order table according to the present embodiment. The startup order table 22a shown in FIG. 2 includes a combination (mode 1) in which the heat source device 52 (air-cooled heat pump) is the startup order 1 and the heat source device 53 (gas absorption type water cooler/heater) is the startup order 2; This includes a combination (mode 2) in which the air-cooled heat pump) is set to start order 2 and the heat source device 53 (gas absorption type cold/hot water machine) is set to start order 1. Note that the activation order 1 means that the activation order is given priority over the activation order 2.

The input unit 23 inputs a file (data) indicating the first operation plan created by the first operation plan creation device 4.

The second operation plan creation unit 24 generates one combination (mode 1 or mode 2) selected from the startup order table 22a based on the first operation plan that defines the schedule of each output of each heat source device 52 and 53 for each unit time. ), and the target period of the stop instruction for each heat source device 52 and 53 determined based on the first operation plan.

In the case of the example shown in FIGS. 3 and 4, the second operation plan creation unit 24 determines that the scheduled output of the heat source device 53 (gas absorption type water cooler/heater) is not 0% (0% %) (as shown in FIG. 4), mode 2 (heat source device 53 (gas absorption type cold/hot water device) has priority) is selected from the startup order table 22a in FIG. 2, and the heat source device 53 When the scheduled output of the (gas absorption type water cooler/heater) is 0% all day long (as shown in FIG. 3), mode 1 (the heat source device 52 (air-cooled heat pump) has priority) is selected from the startup order table 22a.

In this case, the second operation plan creation unit 24 determines that in the first operation plan, the time during which the heat source device 53 (gas absorption type cold/hot water machine) is scheduled to operate is included in 24 hours (during one day). If the 24-hour period is a period in which the output is set to reduce power consumption rather than to reduce operating costs in the first operation plan, heat source equipment with lower power consumption and higher operating costs The startup order table 22a shows a combination (mode 2) in which the startup order of the heat source device 53 (gas absorption type water cooler/heater) is prioritized over the startup order of the heat source device 52 (air-cooled heat pump), which consumes more power and has a lower operating cost. Choose from. On the other hand, if the first operation plan does not include a time during which the heat source machine 53 (gas absorption type cold/hot water machine) is scheduled to operate, the second operation plan creation unit 24 Assuming that 24 hours is a period in which the output is set to reduce operating costs rather than reducing power consumption in the first operation plan, the heat source device 52 (air-cooled heat pump) with higher power consumption and lower operating costs A combination (Mode 1) in which the startup order of is given priority over the startup order of the heat source device 53 (gas absorption cold/hot water machine) with lower power consumption and higher operating cost is selected from the startup order table 22a. In this embodiment, for example, on days when the gas heat source is operating, it is assumed that a demand constraint is applied, and the startup order of mode 2 is used, and on days when the gas heat source is not operating, mode 1 is used, which gives priority to the air-cooled heat pump. Use boot order.

In the case of the examples shown in FIGS. 3 and 4, the second operation plan creation unit 24 selects the heat source device 52 (air-cooled heat pump) or the heat source device 53 (gas absorption type cold/hot water machine) during the 24 hours in the first operation plan. The time during which the scheduled outputs of both are 0% is determined as the target period for the stop instruction for both the heat source device 52 (air-cooled heat pump) and the heat source device 53 (gas absorption type cold/hot water machine). In the example shown in FIG. 3 and the example shown in FIG. 4, the periods covered by the stop instruction are from 0:00 to 4:00 and after 23:00. In this case, the heat source device 52 (air-cooled heat pump) and the heat source device 53 (gas absorption type cold/hot water machine) can be activated from 4:00 to 23:00. In the case of the example shown in FIG. 3 or 4, the heat source controller 3 controls the heat source device 52 (air-cooled heat pump) and the heat source device 53 (gas absorption type cold/hot water machine) from 4:00 to 23:00 in the startup order of mode 1. They are operated (number of units controlled) in combination (example in FIG. 3) or combination of mode 2 activation order (example in FIG. 4).

Further, the second operation plan creation unit 24 can modify the period covered by the instruction to stop the heat source device 53 (gas absorption type cold/hot water device) included in the second operation plan, for example, as follows. Hereinafter, the revised second operation plan will be referred to as the third operation plan. The third operation plan is a plan in which the startable time of the heat source device 53 (gas absorption type cold/hot water machine) is more limited than the second operation plan before modification. In the third operation plan, if the following two conditions are met, a period covered by the stop instruction (stop period) is added. The first condition is that the stop period to be added does not correspond to the time during which the heat source machine 53 (gas absorption cold/hot water machine) is scheduled to operate in the first operation plan. The second condition is that the predicted value of power consumption can satisfy the power demand (request for limiting power consumption) without operating the heat source device 53 (gas absorption type water chiller/heater), and that the heat load can be predicted. The value must be satisfied. Regarding the time when these conditions are satisfied, in the third operation plan, a target period for the instruction to stop the heat source device 53 (gas absorption type cold/hot water device) is added to the second operation plan before modification. Note that the second operation plan and the third operation plan are the same with respect to the instruction of the combination of starting orders and the stop instruction to the heat source device 52 (air-cooled heat pump).

As an example, the third operation plan shown in FIGS. 3 and 4 sets the condition that "the predicted value of power consumption can satisfy the power demand (power consumption limit request)" of the second condition described above. Created by setting the predicted power value < 90% of the target demand, and the condition that ``the predicted value of heat load can be satisfied'' is ``the predicted value of heat load is less than 90% of the capacity of the heat source device 52 (air-cooled heat pump).'' has been done. That is, in the third operation plan shown in FIGS. 3 and 4, the stop period does not correspond to the time during which the heat source machine 53 (gas absorption type cold/hot water machine) is scheduled to operate in the first operation plan, and When the predicted power value is less than 90% of the target demand and the expected output value of the heat source device 52 (air-cooled heat pump) is less than 90%, the period when the heat source device 53 (gas absorption type cold/hot water machine) is stopped is determined. It has been created by using the period covered by In the examples shown in FIGS. 3 and 4, it is assumed that the predicted power value is less than 90% of the target demand at all times. In the third operation plan shown in FIG. 3, the time excluding the period from 12:00 to 12:30 when the scheduled output of the heat source device 52 (air-cooled heat pump) is 90% or more in the first operation plan is This is the period covered by the suspension instruction for gas absorption type water chillers/heaters. In this case, according to the third operation plan shown in FIG. 3, the heat source controller 3 can start the heat source machine 53 (gas absorption cold/hot water machine) from 12:00 to 12:30.

On the other hand, in the example shown in FIG. 4, in the first operation plan, the scheduled output of the heat source device 52 (air-cooled heat pump) is not 90% or more, but from 10:00 to 16:00 the expected value of the output of the heat source device 53 (gas absorption type In the third operation plan, the period excluding the period from 10:00 to 16:00 is set as the period covered by the stop instruction for the heat source device 53 (gas absorption type cold/hot water machine). . In this case, according to the third operation plan shown in FIG. 4, the heat source controller 3 can start the heat source machine 53 (gas absorption cold/hot water machine) from 10:00 to 16:00.

In other words, when creating the second operation plan, the second operation plan creation unit 24 calculates the power consumption of the heat source device 53 (gas absorption type cold/hot water machine) (=power consumption) in the first operation plan for each unit time. There is no output setting for the heat source device (hereinafter referred to as the first heat source device) with a smaller value and higher operating cost, and the predicted value of the predetermined power load is less than the predetermined first threshold value, and the secondary side heat load The second operation plan is corrected by setting the period in which the predicted value of 51 is less than a predetermined second threshold value as the period covered by the stop instruction for the heat source device 53 (gas absorption type cold/hot water machine) (=first heat source device). (create a third operation plan). Here, the predetermined power loads include, for example, the power load of the heat source device 52, the power load of the primary pump 54, the power load of the secondary heat load 51, and the installed secondary heat load 51. Includes the equipment and power loads of the facilities. For example, part or all of the predicted value of the predetermined power load can be included in the first operation plan. Further, the predicted values of the power load of the heat source device 52 and the power load of the primary pump 54 may be, for example, values predicted when operated based on the second operation plan. Here, the first threshold value is set to have a predetermined first margin amount with respect to the target power demand, and the second threshold value is set to have a predetermined second margin amount with respect to the capacity of the heat source device other than the first heat source device. It can be set to have For example, the fact that the predicted value of a predetermined power load is less than a predetermined first threshold value can mean that the predicted power value is less than 90% of the target demand, and in this case, the first margin is less than the target demand. 10% of Furthermore, the fact that the predicted value of the secondary side heat load 51 is less than the predetermined second threshold value means that, for example, the predicted value of the heat load is less than 90% of the capacity (rating) of the heat source device 52 (air-cooled heat pump). In this case, the second margin amount is 10% of the capacity.

On the other hand, the instruction transmitting unit 25 sends a signal instructing the starting order when executing the schedule (on the scheduled execution date) based on the second operation plan or the third operation plan created by the second operation plan creation unit 24. is transmitted to the heat source controller 3 via the communication unit 21, and a stop instruction to stop (or enable starting) the heat source device 52 and the heat source device 53 is sent to the heat source controller 3 via the communication unit 21, for example, every unit time. Send.

Next, with reference to FIG. 5, the processing flow of the heat source control system 1 and the first operation plan creation device 4 shown in FIG. 1 will be described. FIG. 5 is a schematic diagram showing the flow of processing according to an embodiment of the present invention. FIG. 5 shows the flow of processing for creating the first to third operation plans in the heat source control system 1 and first operation plan creation device 4 shown in FIG. 1.

In the process shown in FIG. 5, first, the first operation plan creation device 4 creates a first operation plan for one day at 30-minute intervals using mathematical programming (S11). At this time, the first operation plan creation device 4 creates the first operation plan so as to satisfy the power demand constraints, with the goal of energy saving, cost saving, or CO2 reduction.

Next, the second operation plan creation unit 24 creates a second operation plan in which the vehicle is operated during a certain period of time in the first operation plan (S12). At this time, the second operation plan creation unit 24 considers that demand constraints were applied on the days when the heat source machine 53 (gas absorption type cold/hot water machine) was in operation, and selects the startup order of mode 2, On days when the heat source device 53 (gas absorption type water cooler/heater) is not operating, the activation order of mode 1 is selected in which the heat source device 52 (air-cooled heat pump) has priority.

Next, the second operation plan creation unit 24 calculates the power consumption of the heat source devices when the heat source controllers 3 operate under the control of the number of heat source devices and the predicted power value of the electric power of the other than the heat source devices from the second operation plan (S13). Here, the predicted power value of the power other than the heat source device can be calculated by the first operation plan creation device 4 and included in the first operation plan, for example.

Next, the second operation plan creation unit 24 determines the following conditions at 30 minute intervals (S14). That is, the second operation plan creation unit 24 determines that "the gas absorption type water chiller/heater is not operated in the first operation plan (S15)" and "the predicted electric power value < 90% of the target demand (S16)" and that "the heat It is determined whether the condition of "Load predicted value < 90% of the capacity of the air-cooled heat pump (S17)" is satisfied or not, and for the 30 minutes that satisfy the condition, it is decided to exclude the gas absorption type water cooler/heater (S18 ).

The second driving plan creation unit 24 modifies the driving plan for one day at 30-minute intervals (creates a third driving plan) by repeating the determination process of S14 (S19). The second operation plan creation unit 24 sets exclusion based on the safety factor with the predicted load, since it is best not to operate in the optimal solution during the time when the heat source device 53 (gas absorption chiller/heater) is not operating in mode 2. and stop it. This is a safety factor to ensure that the power does not exceed the target demand and a safety factor to ensure that the supply heat load is not insufficient. Note that the threshold value of 90 is changed as appropriate. The result of taking this exclusion into consideration is the third operation plan, which is the final plan.

Next, with reference to FIG. 6, a system will be described in which a storage battery (not shown) and a storage battery controller 7 for controlling the storage battery are added to the air conditioning system 100 shown in FIG. 1. FIG. 6 is a schematic diagram showing a configuration example of a system according to an embodiment of the present invention. In the system shown in FIG. 6, the first operation plan creation device 4 (not shown in FIG. 6) shown in FIG. A power supply operation plan (S110), which is an operation plan for each storage battery to be controlled, is calculated as an optimal solution (S106) using mathematical programming (S105).

When calculating the optimal solution (S106) by mathematical programming (S105), the first operation plan creation device 4 uses power load prediction other than air conditioning heat source (S101), air conditioning load (cooling/heating) prediction (S102), weather The latest information indicating the prediction (S103), remaining battery capacity (S104), etc. is input. In addition, in the process of calculating the optimal solution (S106) using mathematical programming (S105), heat source/auxiliary equipment performance settings (S201), condition settings such as basic unit (S202), equipment model (heat source equipment, power supply equipment, load, purchase Each piece of information representing the electricity (S203), heat/power balance model (S204), objective function (S205), constraint conditions (S206), etc. is defined in advance. Then, in the process of calculating the optimal solution (S106) using mathematical programming (S105), the operation plan for the heat source and power source that meets the target demand, saves energy, saves costs, reduces CO2, and satisfies the air conditioning load is calculated as the optimal solution (S106). be done.

Next, the second operation plan creation unit 24 (not shown in FIG. 6) shown in FIG. A plan (second operation plan or third operation plan) is created (S107). Then, the heat source controller 3 is controlled based on the created heat source operation plan (second operation plan or third operation plan) (S108).

Furthermore, the storage battery controller 7 is controlled based on the power supply operation plan (S110) included in the optimal solution (S106).

As described above, according to the present embodiment, it is possible to reflect the ideal optimal solution determined by the optimal operation plan of the equipment in the actual automatic control system (heat source controller 3 and heat source system 5). That is, according to this embodiment, for example, using the functions of the general-purpose heat source controller 3, it is possible to perform operation as close to the optimal solution as possible. That is, according to this embodiment, even if an existing heat source controller is used, operation close to optimal operation such as energy saving and cost saving is possible.

In addition, even if operation is performed based on optimal operation, operation time due to exclusion of equipment undergoing maintenance, malfunctioning equipment, and rotation (for example, when there are multiple heat source equipment of the same type) will ensure the reliability of operation of the heat source equipment. system protection such as equalization of heat load, control of the number of units due to fluctuations in secondary heat load (automatic increase/decrease stages for only necessary equipment), automatic increase in stages when the water supply temperature rises, and automatic decrease in stages when the return temperature decreases, etc. to maintain performance. functions are available.

Although the embodiments of the present invention have been described above with reference to the drawings, the specific configuration is not limited to the above-described embodiments, and may include design changes without departing from the gist of the present invention. For example, the number and type of heat source devices are not limited to two or two types. Moreover, the number of heat source controllers 3 may be plural.

Furthermore, part or all of the program executed by the computer in the above embodiments can be distributed via a computer-readable recording medium or a communication line.

100...Air conditioning system, 1...Heat source control system, 2...Central control device, 3...Heat source controller, 4...First operation plan creation device, 5...Heat source system, 21...Communication unit, 22...Storage unit, 23...Input unit , 24... Second operation plan creation section, 25... Instruction transmission section, 31... Communication section, 32... Number control section, 33... Stop control section, 34... Input/output section, 51... Secondary side load, 52, 53... Heat source device, 54, 55...Primary pump, 56, 57...Temperature sensor, 58...Flow rate sensor, 61, 62...Header, 63, 64...Piping

Claims (5)

A system for controlling multiple heat source devices, comprising a heat source controller and a central control device,
The heat source controller is
a number control unit that increases or decreases the number of operating heat source devices according to a startup order instructed by the central control device in accordance with fluctuations in the secondary side heat load;
a stop control unit that stops the instructed heat source device based on a stop instruction received from the central control device;
has
The central control device includes:
a storage unit that stores a boot order table including a plurality of combinations of the boot orders;
the combination of one selected from the startup order table based on a first operation plan that defines the schedule of each output of each heat source device for each unit time, and the target period of the stop instruction determined based on the first operation plan; a second operation plan creation unit that creates a second operation plan that defines the
A heat source control system comprising: an instruction transmitter configured to transmit the start order instruction and the stop instruction to the heat source controller based on the second operation plan. When creating the second operation plan, the second operation plan creation unit is configured to set the output for a period in which the output is set to reduce power consumption rather than to reduce operating costs in the first operation plan. , the combination in which the startup order of the heat source device with the lower power consumption and the higher operating cost is prioritized over the startup order of the heat source device with the higher power consumption and the lower operating cost. The heat source control system according to claim 1, wherein the selection is made from the activation order table. The first operation plan includes a predicted value for each unit time of a predetermined power load including those other than the heat source equipment,
When creating the second operation plan, the second operation plan creation unit selects the heat source equipment (the first 1 heat source device) does not have the output setting, and the predicted value of the predetermined power load including those other than the heat source device is less than the predetermined first threshold, and the predicted value of the secondary side heat load is The heat source control system according to claim 2, wherein a period during which the temperature is less than a predetermined second threshold is a period covered by the stop instruction for the first heat source device. The first threshold is set to have a predetermined first margin with respect to the target power demand,
The heat source control system according to claim 3, wherein the second threshold value is set to have a predetermined second margin with respect to the capacity of the heat source devices other than the first heat source device. A method for controlling multiple heat source devices, the method comprising:
Using a heat source controller and a central control device,
In the heat source controller,
a step of increasing or decreasing the number of operating heat source devices according to a startup order instructed by the central control device according to fluctuations in the secondary side heat load;
Stopping the instructed heat source device based on a stop instruction received from the central control device;
In the central control device,
Determined based on one combination selected from a startup order table including a plurality of combinations of startup orders based on a first operation plan that defines the schedule of each output of each heat source device for each unit time, and the first operation plan. creating a second operation plan that specifies the period covered by the stop instruction;
A heat source control method comprising: transmitting the start order instruction and the stop instruction to the heat source controller based on the second operation plan.

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